A microelectronic assembly incorporates units stacked one above the other and may include a plurality of similar stacks mounted to a circuit board. Some of the stacks may be inverted, rotated or both relative to other stacks so that corresponding edges of the stacks face one another to facilitate communication between the stacks. Communication between the stacks may be carried along traces on one or more interposers intercepting the stacks remote from the circuit board. Within each stack, conducting paths may extend in vertical columns or in other arrangements such as a stair step arrangement wherein each conductive path traverses a series of column positions, or in a crossing arrangement such two conductive paths cross back and forth between column positions along the vertical extend of the stack. A stack may include portions disposed above and below the circuit board.
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16. A microelectronic assembly comprising:
(a) a stack including:
(i) an upper unit having first and second regions, said upper unit having downwardly facing unit terminals in said first region; and
(ii) a lower unit having first and second regions, said lower unit having upwardly facing unit terminals in said first region of said lower unit, said upper unit being disposed over said lower unit with said first regions of said upper and lower units aligned with one another and with said second regions of said upper and lower units aligned with one another; and
(b) an interposer extending between said first regions but not extending between said second regions, said interposer having interposer terminals thereon, at least some of said unit terminals of said upper unit being electrically connected to at least some of said unit terminals of said lower unit through said interposer terminals.
8. A microelectronic assembly comprising:
(a) a circuit panel;
(b) a plurality of units each including one or more microelectronic elements, each said unit having a top surface, a bottom surface, each said unit having unit terminals on at least one of said surfaces,
said units being disposed in a plurality of stacks including first and second stacks, each said stack including a plurality of said units superposed on one another in top-surface to bottom surface arrangement, at least some of the unit terminals on each unit being connected to at least some of the unit terminals on other units in the same stack, said stacks being mounted to said circuit panel; and
(c) an interconnect interposer including a dielectric element and conductors, said interconnect interposer extending horizontally between said first and second stacks remote from said circuit panel, at least some unit terminals in a said first stack being electrically connected to at least some unit terminals in said second stack through said conductors of said interposer.
45. A microelectronic assembly comprising a plurality of units, each including at least one microelectronic element, each said unit having a top surface, a bottom surface and contacts exposed at said top and bottom surfaces, each said unit defining horizontal directions, said units being superposed on one another to form a stack having a vertical direction and having column positions such that each column position lies at the same horizontal location in each unit, at least some of said contacts on each unit are connected to one another to form conductive paths extending between said units, said conductive paths including at least one pair of crossed paths, each said pair of crossed paths including a first one of said paths and a second one of said paths, such that in a first part of the stack the first path extends at a first column position and the second path extends at a second column position, whereas in a second part of the stack, above or below the first part of the stack, the first path extends at said second column position and the second path extends at said first column position.
25. A component for use in a microelectronic assembly, said component comprising:
(a) a structure including at least one dielectric element, said support structure having top and bottom surfaces extending in horizontal directions; and
(b) top unit terminals exposed at said top surface and bottom unit terminals exposed at said bottom surface, said top and bottom unit terminals being disposed at column positions such that top and bottom terminals disposed at the same column position are aligned with one another along an axis extending in a vertical direction transverse to said horizontal directions, said terminals including:
(i) a set of A terminals including an A top unit terminal at a first column position and an A bottom unit terminal at a second column position, said A terminals being electrically connected to one another; and
(ii) a set of b terminals including a b top unit terminal at said second column position and a b bottom unit terminal at said first column position, said b terminals being electrically connected to one another but not connected to said A terminals by any element of said substrate.
44. A microelectronic assembly comprising a plurality of units, each including at least one microelectronic element, each said unit having a top surface, a bottom surface and contacts exposed at said top and bottom surfaces, each said unit defining horizontal directions, said units being superposed on one another to form a stack having a vertical direction and having column positions such that each column position lies at the same horizontal location in each unit, at least some of said contacts on each unit are connected to one another to form conductive paths extending between said units, said conductive paths including at least one group of crossed paths, each said group of crossed paths including a first set of paths and a second set of paths such that in a first part of the stack the first set of paths extends at a first set of column positions and the second set of paths extends at a second set of column positions, whereas in a second part of the stack, above or below the first part of the stack, the first set of paths extends at said second set of column positions and the second set of paths extends at said column positions.
1. A microelectronic assembly comprising:
(a) a circuit panel having top and bottom surfaces;
(b) a plurality of units each including one or more microelectronic elements, each said unit having a top surface, a bottom surface and edges extending between said top and bottom surfaces, each said unit having terminals at column positions on at least one of said surfaces,
said units being disposed in a plurality of stacks,
each said stack including a plurality of said units superposed on one another in top-surface to bottom surface arrangement with the top surfaces of the units facing toward the top of the stack and with terminals at the same column positions in different units of the stack aligned with one another in columns extending upwardly and downwardly within the stack,
said stacks being mounted to the circuit panel so that a first set of said stacks are disposed in a first orientation with the top surfaces of the units facing upwardly and a second set of said stacks are disposed in a second orientation with the top surfaces of the units facing downwardly, at least some of said stacks of said first set and at least some of said stacks of said second set being disposed side-by-side with one another.
48. A stackable microelectronic unit comprising:
(a) a dielectric element having top and bottom surfaces, a central region, and first and second side regions disposed on opposite sides of said central region,
(b) terminals exposed at said top and bottom surfaces of said dielectric element, said terminals including at least one row of common terminals extending in said central region; and
(c) first and second substantially identical microelectronic elements, each said microelectronic element having a front surface and contacts exposed at said front surface, said contacts including common contacts and unique contacts, said front surface having a first edge, said first microelectronic element being mounted to said dielectric element on a first side of said central region with said front surface facing downwardly and said first edge adjacent said central region, said second microelectronic element being mounted to said dielectric element in said first side region with said front face facing downwardly and with said first edge adjacent said central region, said second microelectronic element being mounted to said dielectric element in said second side region with said front face facing upwardly and with said first edge adjacent said central region, at least some of said common contacts being connected to at least some of said common terminals.
47. A microelectronic assembly including:
(a) a plurality of units, each having a structure including at least one dielectric element defining top and bottom surfaces and horizontal directions, each said structure having and terminals disposed at column positions such that each column position denotes a location in said horizontal directions, each said unit including a microelectronic element, the microelectronic elements of said units being substantially identical to one another, each said microelectronic element having contacts, at least some of said contacts being common contacts, at least some of said terminals on each said microelectronic element being common terminals electrically connected to said common contacts, said common terminals being disposed at the same column positions and connected to the same common contacts in each said unit,
(b) a circuit panel having upper and lower surfaces and having horizontal directions, upper pads exposed at said upper surface and lower pads exposed at said lower surface, said pads including common pad pairs, each such common pad pair including one of said upper pads and one of said lower pads, the pads of each such pair being electrically connected to one another and substantially aligned with one another in the horizontal directions of said circuit panel;
said units being superposed on one another in a stack with a lower portion of the stack disposed below said circuit panel and an upper portion of the stack disposed above the circuit panel, the top surfaces of all of said units facing upwardly, said common terminals of all of the units being aligned with one another and with said common pairs of pads, the aligned common terminals and common pairs being connected to one another.
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(i) a set of C terminals including a C top unit terminal at a third column position and a C bottom unit terminal at a fourth column position, said C terminals being electrically connected to one another; and
(ii) a set of D terminals including a D top unit terminal at said fourth column position and a D bottom unit terminal at said third column position, said D terminals being electrically connected to one another,
and wherein said upper pads of said circuit panel include a third upper pad connected to the bottom D terminal of said second unit and a fourth upper pad connected to the bottom C terminal of said second unit, said lower pads of said circuit panel including a third lower pad connected to the top C terminal of said third unit and a fourth lower pad connected to the top D terminal of said third unit.
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This application claims the benefit of the filing date of U.S. Provisional Patent Application No. 60/517,179, filed Nov. 4, 2003, the disclosure of which is hereby incorporated by reference herein.
The present invention relates to microelectronic packaging and systems.
Microelectronic elements such as semiconductor chips are commonly provided in packages having terminals connected to the microelectronic element itself, such terminals being available for connection to external elements such as printed circuit boards.
Some microelectronic elements, notably memory chips, have been provided heretofore in stacked arrangements with packages superposed one atop the other to conserve space on a circuit board. Such structures typically involve only a few chips and relatively simple connections which normally do not involve interconnections between chips in the stack, or between multiple stacks of chips. Even in these situations, it is sometimes necessary to provide different packages for different chips in the stack.
One aspect of the present invention provides a stacked packaging arrangement especially useful for, e.g., logic chips such as field programmable gate arrays (hereinafter “FPGA”) or microprocessors, in which the stacked packaging arrangement accommodates logical interconnections between chips where inputs from one chip are connected to outputs of other chips. A further aspect of the invention provides designs for individual units and elements which can be used in such stacked arrangement. Yet another aspect of the invention provides a system-level design which allows for integration of multiple stacked packages while minimizing the complexity of signal routing in a printed circuit board (“PCB”) or other circuit panel used in the system. Still other aspects of the invention provide unit configurations which facilitate routing of signals to chips on different packages in a stack.
A system according to one embodiment of the invention uses a plurality of units 30 (
Each unit also includes a first microelectronic element in the form of a semiconductor chip 41, in this case, an FPGA. In the particular design illustrated, each unit also includes additional semiconductor chips or SRAMs 43. The SRAM within each unit cooperates with the FPGA of that particular unit. In the embodiment illustrated, the FPGA chip is flip-chip mounted to the top of the unit substrate, so that the unit substrate serves as the package for the FPGA. The SRAMs are supplied in separate chip size packages, which are LGA-bonded to the bottom side of the unit substrate. Any other chip mounting techniques can be used.
One portion of a unit substrate 32 is shown in
Although the particular embodiment is described with reference to solderable units, it should be appreciated that units having other forms of terminals on their top and bottom sides can be employed. Merely by way of example, the terminals may be in the forms of pins and sockets, metallic bumps or other conductive contacts. Also, it is not necessary to employ a flat, board-like, or tape-like substrate such as the substrate depicted. For example, each unit substrate may be a ceramic or other chip carrier having a pocket or hole arranged to receive the chip or chips and having contacts on top and bottom sides of the substrate. Indeed, where a single semiconductor chip incorporates all of the functions required within a single unit, the chip itself can be provided with terminals on its top and bottom sides, so that each unit consists only of the chip. In a further variant, some or all of the terminals on the top and bottom sides of the substrate may be formed by common elements. For example, as disclosed in co-pending, commonly assigned U.S. patent application Ser. No. 10/267,450, filed Oct. 9, 2002, the disclosure of which is incorporated by reference herein, a terminal in the form of a pad disposed on one surface of the substrate may be exposed to the opposite surface of the substrate through a hole in the substrate, so that the same pad defines terminals exposed at both sides of the substrate. The SRAM chips incorporated within each unit cooperate with the FPGA of such unit. Each unit incorporates appropriate connections (not shown) between the SRAM and the FPGA.
As best seen in
The units within each stack are aligned with one another in their horizontal directions, so that terminals on all of the units in the same column position are vertically superposed above one another. Stated another way, a vertical line drawn through a terminal at a particular column position on one unit will pass through all of the other terminals at the same column position on the other units in the stack.
At numerous column positions, the terminals of all of the units within the stack are connected so that all of the terminals disposed at the same column position are connected to one another and connected to the printed circuit board. In this arrangement, referred to as a “normal stack connection” and shown in
As further discussed below, elements referred to herein as interposers 60 and 62 (shown as transparent planes with broken line borders in
At those column positions where a straight-through or normal connection runs throughout the entire stack, printed circuit board 44 has a pair of upper and lower pads 48 and 52 referred to herein as a “common pair.” One such common pair includes pads 48a and 52a (
As best seen in
At those column positions where a normal stack connection, as discussed above with reference to
The upper interposer 60 is connected in each of the other stacks 42-1 through 42-3 in the same manner. The lower interposer (62;
The various first microelectronic elements or FPGAs 41 located within the stacks are interconnected with one another. At each such interconnection, an output of one FPGA is connected to an input of another FPGA. As mentioned above, the internal structure of every unit is identical to the individual structure of every other unit. For example, each unit has a top terminal at a given column position connected to an output or contact of the FPGA chip itself. Likewise, each unit has a top terminal at another position, connected to an input pad on the FPGA of the unit. Thus, connecting all of the terminals at the same column position within a particular stack to one another would not connect inputs to outputs, but instead would short inputs together and short outputs together.
To provide connections between inputs and outputs of the first microelectronic elements or FPGAs of adjacent units within a stack, the terminals associated with the input and output pads are arranged and connected as shown at
Here again, top and bottom terminals on adjacent units in the stack disposed at the same column position are connected to one another by conductive elements 90. Conductive elements 90 are depicted as simple solder ball interconnects in
The bottom A terminal 40-A(1) of the top-most unit 30-1 is connected to the top B terminal 38-B(2)of the next lower unit 30-2. Conversely, the bottom B terminal of the top-most unit 30-1 is connected to the top A terminal 38-A(2) of the next lower unit 30-2. Thus, the A terminals of each unit are connected to the B terminals of the adjacent unit, so that the output or A pad of the FPGA 41 (
The connection discussed with reference to
In other instances, it is necessary to make connections between the output connections of the FPGA in one unit in a stack and the input or B connections of the FPGA in another, non-adjacent unit in the same stack. The arrangements used for such connections are shown in
In each unit, the A terminals are connected to an output pad of the first microelectronic element or FPGA. However, the B terminals are not connected to a pad of the FPGA. The C terminals are connected to an input pad of the FPGA carried by the unit, whereas the D terminals are not connected to a pad of the FPGA. Here again, the bottom terminals of each unit are connected to the top terminals of the next adjacent unit, except that the bottom terminals of second unit 30-2 are connected to the upper pads 48 of PCB 44 disposed at the same column positions, whereas the top terminals of unit 30-3, disposed immediately below the PCB 44, are connected to the lower pads 52 of the PCB at the same column positions. In this instance, the upper pad 48 at each column position of the first through fourth column position shown in
The PCB also has an upper pad 48-U2 at the second column position CP2 connected to a lower pad 52-L4 at the fourth column position CP4. The output of unit 30-2 is connected through these upper and lower pads on the PCB and through the other units to terminal 30-C(4) of unit 30-4. Likewise, the PCB has a lower pad 52-L(1) at the first column position CP1 connected to an upper pad 48-U3 at the third column position CP3, and also has a lower pad 52-L2 at the second column position CP2 connected to an upper pad 48-U4 at the fourth column position CP4. The lower pad 52-L1 at the first column position, in conjunction with the conductive paths defined by the units, connect the A terminals, and hence the FPGA output contact of unit 30-3 to the C terminals, and hence the FPGA input, of unit 30-1. The lower pad 52-L2 at the second column position and upper pad 48-U4 at the fourth column position serve to connect the A terminals, and hence the FPGA output contact of unit 30-4 to the C terminals, and FPGA input contact of unit 30-2.
At still other locations within each stack, there are unique connections between the units of the stack and the printed circuit board. That is, a signal is routed from the PCB to only one unit in the stack. Where these unique connections are desired, top terminals 38 and bottom terminals 40 are provided on each unit at a set of four column positions CP1 through CP4 as shown in
Moreover, each conductive path runs to the highest-ordered column position at top of the unit where the connection reaches the lowest-ordered column position. For example, the conductive path from terminal 40-3(4), at the third column position on the bottom of unit 30-4 runs up to bottom terminal 40-1(2) at CP1 on unit 30-2, and then to top terminal 38-4(2) at CP4 on the same unit 30-2. The conductive path thus connects to bottom terminal 40-4(1) on the bottom of unit 30-1 and thus to top terminal 38-3(1) at CP3, on the top of the top unit 30-1. Thus, each of the conductive paths extends through all four of the units, and ultimately returns to the same column position as it had at the bottom of the stack. Stated another way, the “stair-step” arrangement is topologically similar to a spiral staircase; in connection involving a set of N column positions, the arrangement repeats after N units. As further discussed below in connection with
The discussion above refers to connections with the first microelectronic element or FPGA in each of the various units. Any or all of these techniques can be used to provide connections with the second microelectronic elements in each of the various units.
The foregoing discussion relates to connections within each individual stack. However, it is also necessary to connect units in different stacks to one another. In particular, inputs and outputs of FPGAs in units of different stacks must be connected to one another. Several features of the system facilitate these inter-stack interconnections. First, as seen in
As seen in
By routing inter-stack interconnections through the interposers, which are separate from the PCB 44, the PCB can be greatly simplified. Further, packaging each FPGA with its associated SRAMs also avoids the needs for traces on the PCB for interconnecting FPGAs with SRAMs. The PCB, thus, can have many fewer layers than would be required otherwise.
As one example, a conventional PCB with four FPGAs mounted directly on the PCB, and with SRAMs connected to the FPGAs through the printed circuit board itself, requires a printed circuit board with more than 25 layers. Such a circuit board is extraordinarily complex, and hence suffers significantly in cost and reliability. By contrast, the design as discussed above can accommodate 16 FPGAs and 32 SRAMs in the same circuit board area or less, using a PCB having fewer layers.
The features discussed above can be varied. For example, where an interposer is present between units in a stack, the mezzanine interposer may be provided with A and B pads at first and second column positions, as discussed above with reference to
Also, the individual features discussed above can be utilized separately. For example, an arrangement utilizing a stack with portions disposed above and below a printed circuit board or other circuit panel, also referred to as a “mirrored” stack, is advantageous in and of itself, even where only one stack is used. Inter alia, by reducing the stack height on each side of the printed circuit board, cooling of the individual dies is greatly facilitated. Moreover, this result is achieved without the use of special “mirror image” sets of chips. As seen in
Also, chips other than FPGAs may be utilized. The number of chips per unit, the number of units per stack, and the number of stacks all can be increased or decreased.
In the stacked packages discussed above, each unit has been described as having top and bottom terminals on the top and bottom surfaces of a single unit substrate. However, this is not essential. A unit 130 according to a further embodiment of the invention (
The ability to use a single metal structure in the main substrate is a significant advantage. Although the interposer typically is a two metal structure, the interposer occupies a smaller area than the main substrate. As the cost penalty associated with fabrication of a two metal structure is incurred only over a smaller area, the costs of fabricating the entire assembly are reduced. Also, as best seen in
In the embodiment illustrated in
Stair step routing within units can be used, for example in forming stacks of memory chips. A typical memory chip package of a type used without stair step routing is depicted in
By contrast, using the approach shown in
A unit 230 according to a further embodiment of the invention includes a main substrate 202 and an interposer 206 similar to those discussed above. However, interposer 206 provides crossover routing similar to that discussed above with reference to
Alternatively, units made using an interposer with crossover routing can be used to minimize the number of separate tapes required for making a memory stack as discussed above. In this arrangement, the main substrate may be a tape with the same configuration as the A tape discussed above with reference to
A unit according to a further embodiment of the invention (
In a further embodiment, microelectronic element 308B is made with a substantially identical function to element 308A but with contacts 312 disposed in a mirror image of the contact pattern on microelectronic element 308A. In this case, both microelectronic elements may be mounted on the top surface and still provide the desired contact arrangement as seen in
As mentioned above, various types of conductive elements can be used to interconnect the terminals of the units with one another. For example, dielectric elements with pins are shown in U.S. Provisional Patent Applications 60/533,210;60/533,393 and 60/533,437, all filed Dec. 30, 2003, the disclosures of which are incorporated by reference herein. The use of such pins as connecting elements in a stacked package is described in U.S. Provisional Patent Application 60/583,066, filed Jun. 25, 2004, and in the provisional patent application entitled Stacked Packages With Pin Conductors and Chip Select Elements, filed on or about Oct. 25, 2004, the disclosures of which are also incorporated by reference herein. Other forms of stacked packages using other types of pins are disclosed in PCT Published International Application WO2004/077525, the disclosure of which is also incorporated by reference herein.
Also, other features useful in stacked packages are disclosed in U.S. Published Patent Applications 20030107118 and 20040031972, the disclosures of which are also incorporated by reference herein. For example, these published applications describe features which can be incorporated into the units of a stacked package to allow selective making or breaking of traces in the individual units, to provide still further routing versatility. These features can be used in conjunction with the features discussed above.
Also, it should be appreciated that terms such as “top”, “bottom”, “up”, “down” and the like as used in this disclosure refer to the frame of reference of the structure itself, and need not correspond to the normal gravitational frame of reference. Further, terminals and other conductive features are described herein as being “exposed at” certain surfaces of dielectric elements. As used in this disclosure, a conductive feature is “exposed at” a surface of a dielectric element if the conductive feature is accessible for contact with a point moving toward such surface from outside the dielectric element. Thus, a conductive feature exposed at a surface of a dielectric element may project from such surface; may be flush with such surface; or may be recessed below such surface in a hole or depression in such surface.
In the drawings, the vertical directions of the various components are shown as perpendicular to the horizontal directions. This is the most commonly used arrangement. However, a stack may have a sloping vertical direction, oblique to the horizontal planes of the unit substrates as, for example, where the conductive elements connecting terminals on adjacent unit substrate are canted. Also, the vertical direction may change slope at one or more places along the vertical extent of the stack, so that a “vertical” line zigags, as where alternate layers of conductive elements are canted in opposite directions. Any of these arrangements can be used.
As these and other objects, features and advantages of the present invention can be utilized without departing from the present invention, the foregoing description of the preferred embodiments should be taken by way of illustration rather than by way of limitation of the present invention.
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